TOR: the first 10 years.

TOR was discovered and christened 10 years ago. On the occasion of this anniversary, we revisit the discovery of TOR and chronicle subsequent breakthroughs in S. cerevisiae that contributed to an understanding of TOR function in yeast and higher eukaryotes. In particular, we discuss findings that led to the realization that the function of TOR is to control cell growth in response to nutrients.

The PH domain of the yeast GEF Rom2p serves an essential function in vivo.

In a screen designed to identify new upstream components of the Pkc1p-MAP kinase signal transduction pathway that responds to cell wall damage in yeast, we identified a new mutant allele of the ROM2 gene, which encodes a GDP/GTP exchange factor that acts on Rho1p. This allele, originally termed ubk1 (upstream of Bck1p) encodes a truncated protein that lacks the putative PH domain. Complementation experiments showed that genes coding for several known components of the pathway are able to suppress the ubk1 mutation to various degrees when introduced on low- or high-copy-number vectors. Analysis of several rom2 mutants showed that mutants in which the PH domain is deleted result in a phenotype indistinguishable from that of a strain deleted for the entire gene, indicating that this domain fulfills an essential function in vivo. Furthermore, we found that the growth phenotype of rom2 mutants is highly dependent on the strain background. Surprisingly, analysis of the phosphorylation status of Mpk1p in these mutants showed an elevated level of doubly phosphorylated Mpk1 protein, indicating that the growth defect of rom2 mutants is not due to an inability to activate the MAP kinase module, but rather to lack of a function of the Rom2 protein that has yet to be identified precisely.

Lrg1p functions as a putative GTPase-activating protein in the Pkc1p-mediated cell integrity pathway in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae the ROM2 gene encodes a GDP/GTP exchange factor for the small G-protein Rho1p, a known activator of protein kinase C. In a screen designed to isolate suppressors of a rom2 mutant allele, we identified a mutant defective in the gene coding for the putative GTPase-activating protein Lrg1p. This protein was previously suggested to be involved in sporulation and mating. Here we provide evidence for its role in Pkc1p-mediated signal transduction based on the following results. (1) Deletion of LRG1 suppresses the growth phenotypes associated with mutations in SLG1 (which codes for a putative sensor of cell wall damage). (2) Using two-hybrid assays an interaction between the GAP domain of Lrg1p and Rho1p was demonstrated. (3) The lrg1 mutant shows enhanced activity of the Pkc1p pathway. (4) Overexpression of LRG1 leads to a cell lysis defect that can be suppressed by the addition of osmotic stabilizers. Phenotypic comparison of lrg1 mutants with mutants defective in other GTPase-activating proteins (Sac7p, Bem2p, Bag7p) presumed to act on Rho1p revealed that deletion of SAC7, but not BEM2 or BAG7, suppresses the phenotype of rom2 mutants. Pairwise combination of mutations in all these genes showed that the simultaneous deletion of SAC7 and LRG1 is synthetically lethal. We therefore suggest that Lrg1p acts as a negative regulator of the Pkc1p pathway in conjunction with its known homologue Sac7p.

Comparative genetic and physiological studies of the MAP kinase Mpk1p from Kluyveromyces lactis and Saccharomyces cerevisiae.

MAP kinases are essential components of signal transduction pathways in yeasts and higher eukaryotes. Here, we report on the isolation of the gene encoding the MAP kinase KlMpk1p by complementation of the respective Saccharomyces cerevisiae deletion mutant with a genomic library from Kluyveromyces lactis. Sequencing revealed the presence of an open reading frame capable of encoding a protein of 520 amino acid residues with a deduced molecular mass of 59.726 Da. The deduced protein sequence displayed a high degree of similarity to known MAP kinases from yeast to man, with an overall identity of 70 % to ScMpk1p. One-hybrid analysis demonstrated the presence of a cryptic transcriptional activation domain in the C-terminal part of the protein. Deletion of this sequence in ScMpk1p resulted in a reduced MAP kinase activity (measured by an indirect assay), an increased sensitivity towards caffeine and an increased resistance against Calcofluor white. Complete deletion mutants of Klmpk1 display an osmo-remedial phenotype on rich medium, but are capable of growth in the absence of osmotic stabilization on synthetic medium. As Scmpk1 deletion mutants, they are sensitive to cell surface destabilizing agents such as Calcofluor white and SDS, and growth is inhibited in the presence of 5 mM caffeine. Overexpression of KlMPK1 did not produce a growth defect in S. cerevisiae or in K. lactis.

The protein kinase C-mediated MAP kinase pathway involved in the maintenance of cellular integrity in Saccharomyces cerevisiae.

Signal transduction mediated by the single yeast isozyme of protein kinase C (Pkc1p) is essential for the maintenance of cellular integrity in this model eukaryote. The past few years have seen a dramatic increase in our knowledge of the upstream regulatory factors that modulate Pkc1p activity (e.g. Tor2p, Rom1p, Rom2p, Rho1p, Slg1p, Mid2p) and of the downstream targets of the MAP kinase cascade triggered by it (e.g. Rlm1p, SBF complex). The picture that has emerged connects this pathway to a variety of other cellular processes, such as cell cycle progression (Cdc28p, Swi4p), mating (Ste20p), nutrient sensing (Ira1p), calcium homeostasis (calcineurin, Mid2p, Fks2p) and the structural dynamics of the cytoskeleton (Spa1p, Bni1p).

Genetic and biochemical characterization of phosphofructokinase from the opportunistic pathogenic yeast Candida albicans.

We have used the two PFK genes of Saccharomyces cerevisiae encoding the alpha and beta-subunit of the enzyme phosphofructokinase (Pfk) as heterologous probes to isolate fragments of the respective genes from the dimorphic pathogenic fungus Candida albicans. The complete coding sequences were obtained by combining sequences of chromosomal fragments and fragments obtained by inverse polymerase chain reaction (PCR). The CaPFK1 and CaPFK2 comprise open reading frames of 2961 bp and 2838 bp, respectively, encoding Pfk subunits with deduced molecular masses of 109 kDa and 104 kDa. The genes presumably evolved by a duplication event from a prokaryotic type ancestor, followed by another duplication. Heterologous expression in S. cerevisiae revealed that each gene alone was able to complement the glucose-negative phenotype of a pfk1 pfk2 double mutant. In vitro Pfk activity in S. cerevisiae was not only obtained after coexpression of both genes, but also in conjunction with the respective complementary subunits from S. cerevisiae. This indicates the formation of functional hetero-oligomers consisting of C. albicans and S. cerevisiae Pfk subunits. In C. albicans, specific Pfk activity was shown to decrease twofold upon induction of hyphal growth. CaPfk cross-reacts with a polyclonal antiserum raised against ScPfk and displays similar allosteric properties, i.e. inhibition by ATP and activation by AMP and fructose 2,6-bisphosphate.